Active safety control for dynamic human-robot interaction

In human-robot interaction (HRI) and especially in close or physical interaction, it is essential to ensure the human's safety. This is achieved by introducing virtual constraints defining a region, in which the robot is allowed to move safely. These safety regions may change over time during human-robot interaction, which may be either due to human motion or changed environmental conditions. In consequence it is important for the applied control scheme to handle dynamic boundaries. This work proposes an invariance-based control approach, which enforces adherence to boundaries with dynamic parameters. We extend the invariance control approach, which provides a computationally efficient and systematic method for defining constraints on system states and outputs, such that it handles the constraint dynamics. Stability and invariance properties are analyzed and validated in an experimental evaluation on a 7-DoF anthropomorphic manipulator.

Authors

• Melanie Kimmel
• Sandra Hirche

Keywords

• Control systems
• Robot kinematics
• Safety
• Manipulators
• System dynamics
• Dynamics
• Human-robot Interaction
• Active Safety Control
• Control Strategy
• System State
• Kinetic Parameters
• Experimental Evaluation
• Invariance Property
• Dynamic Boundary
• Invariant Control
• Optimal Control
• Linear System
• Dynamic Environment
• Robotic System
• Output Function
• Internal Dynamics
• Experimental Run
• Output Control
• End-effector
• Robot Manipulator
• State Constraints
• Nominal Control
• Impedance Control
• Constraint Violation
• Multi-input Multi-output Systems
• Admissible Set
• Human Partner
• Boundary Parameters
• Positively Invariant
• Nominal Output
• Cartesian Space